CN103229439A

CN103229439A - Optical communication system, optical transmitter, and transponder

Info

Publication number: CN103229439A
Application number: CN2010800703346A
Authority: CN
Inventors: 佐佐木慎也
Original assignee: Hitachi Ltd
Current assignee: Hitachi Ltd
Priority date: 2010-11-29
Filing date: 2010-11-29
Publication date: 2013-07-31
Also published as: JP5583788B2; WO2012073308A1; EP2648349A1; JPWO2012073308A1; US20130315267A1; US9048953B2

Abstract

The present invention pertains to technology for reducing the desired bandwidth of an optical receiver in an optical OFDM communication system. Optical OFDM signals of different spectra are transmitted alternately for each OFDM symbol time, and after this light is transmitted with an optical fiber the light is converted from light to electricity with a delay interferometer having a delay time equal to one symbol time and with a balance-type direct detection receiver.

Description

Optical communication system, optical transmitter and transponder

Technical field

The present invention relates to optical communication system, optical transmitter and transponder (transponder), be particularly related to the light ofdm communication system that uses multicarrier, more particularly, relate to Multiplexing, OFDM at light OFDM(Orthogonal Frequency Division) reduce optical communication system, optical transmitter and the transponder of the required frequency bandwidth of optical receiver in the communication system.

Background technology

The majority of the optical communication system of practicability has adopted the modulation-demodulation technique that uses 2 values of light intensity at present.Particularly, transmitter side with " 0 " and " 1 " of digital information be converted to light intensity unlatching, close (ON/OFF), send to optical fiber, the light that will propagate in optical fiber carries out opto-electronic conversion at receiver side, with original information recovery.In recent years, along with the fulminant of internet popularized, the message capacity that optical communication system is required improves tremendously.For the demand of the high capacity of message capacity, up to the present, unlatching, the speed of closing by making light, be that modulating speed rises and deals with.But, realize in the method for high capacity the problem of the following stated being arranged generally in that this modulating speed is risen.

If the problem that has the modulating speed of making to rise then shortened by the transmissible distance that CHROMATIC DISPERSION IN FIBER OPTICS limited.The general transmitting range that is limited by chromatic dispersion square shortening by bit rate.That is,, then be subjected to the transmitting range of chromatic dispersion restriction to become 1/4 if bit rate becomes 2 times.Equally, if modulating speed is risen then the problem that shortened by the transmissible distance of the polarization dispersion restriction of optical fiber.Generally speaking, if bit rate becomes 2 times, then be subjected to the transmitting range of polarization dispersion restriction to become 1/2.If represent the influence of chromatic dispersion particularly, if then use monomode fiber with bit rate 10Gbps, then being subjected to the transmitting range of chromatic dispersion restriction is 60km, if but become the system that bit rate is 40Gbps, then its distance shortens and is about 4km.And then, under the situation of follow-on 100Gbps system, be subjected to the transmitting range of chromatic dispersion restriction to become 0.6km, can not realize that like this transmitting range is the trunk optical communication system about 500km.In order to make up superfast trunk optical communication system, the special optical fiber that will have the so-called dispersion compensating fiber of negative chromatic dispersion at present for the chromatic dispersion of offsetting transfer path is arranged in repeater or the transceiver.This special light is expensive, needs to determine to be arranged on the senior design of the amount of the dispersion compensating fiber in transceiver or the optical repeater inside in addition, and the two has raised the price of optical communication system.

So, recently,, use the research of the optical communication system of OFDM technology to receive publicity as the light modulation demodulation mode that message capacity is increased.The amplitude separately of many sine waves (it is called subcarrier) of the frequency of the integral multiple of the inverse of OFDM technology by will mutually orthogonal in the time in 1 code element (symbol), promptly having 1 symbol time and phase settings are the value of regulation, carry (modulation) information thus, use the technology of the signal after these subcarrier packs with carrier wave (conveying ripple) modulation and transmission.This OFDM technology is at telephone office and the inter-household VDSL(Very high bit rate Digital Subscriber Line that communicates by letter, super high bit rate digital subscriber line) electric line communication system in system or the family, also have in the surface wave numeral TV system and use and practicability.And then also plan is used in follow-on mobile telephone system.

The light ofdm communication system is to be carrier wave, the communication system that adopts the OFDM technology with light.In the OFDM technology, use many subcarriers as described above, and then the modulation system of each subcarrier for example can adopt multistage modulation systems such as 4-QAM, 8-PSK or 16-QAM, so that 1 symbol time is compared with the inverse of bit rate is very long.As its result, be subjected to the transmitting range of above-mentioned chromatic dispersion or polarization dispersion restriction to compare long enough with the transmitting range of in optical communication system, imagining (being 500km in the trunk system at home for example), do not need above-mentioned dispersion compensating fiber.As a result, the low cost optical communication system might can be realized.

Use the optical communication system of direct detection receive mode different, square proportional (on the other hand, in wireless communication system, the electric current and the electric field that flow in the reception antenna are proportional) of the absolute value of the photoelectric current that receives and the electric field of light with wireless communication system.Because this feature, so in the light ofdm communication that uses the direct detection receive mode, occur in the problem that does not have in the wireless OFDM communication.That is, because the absolute value of the photoelectric current that receives and optical electric field is square proportional, so the problem that has Beat Signal (beat signal) between subcarrier and original signal to interfere.This is called beat interference between subcarrier below problem.

The prior art document

Non-patent literature

Non-patent literature 1:Brendon J.C.Schmidt, Arthur J.Lowery and Liang B.Du, " Low Sampling Rate Transmitter for Direct-Detection Optical OFDM ", OFC/NFOEC2009, OWM4,2009

Brief summary of the invention

The problem that invention will solve

In light ofdm communication in the past, carried out avoiding the motion that beat is interfered between this subcarrier.This motion is the motion that also sends carrier wave simultaneously and then boundary belt (guard band) is set at frequency axis between these carrier waves and sub-carrier signal beyond sub-carrier signal as the light signal that sends from transmitter.With the frequency spectrum designation of this light ofdm signal in Fig. 3.Observe this figure also as can be known, will send simultaneously, and between carrier wave and ofdm signal, on frequency axis, set boundary belt with frequency bandwidth (B) width about equally of ofdm signal as a plurality of subcarriers and the carrier wave of ofdm signal.The frequency spectrum designation that direct detection is received the photoelectric current under the situation of this light ofdm signal is in Fig. 4.As known in the figure, there is Beat Signal between subcarrier, because they can separate, so do not show influence for receiving feature on frequency axis at the lower frequency side of the signal that should receive originally (Beat Signal of carrier wave and subcarrier).This motion in light ofdm communication in the past, avoid the method that beat is interfered between subcarrier.

In avoiding the method that beat is interfered between this subcarrier, two problems are arranged.At first, in order to generate the light ofdm signal of frequency spectrum with Fig. 3, in carrying out needing also carrier wave is included in when signal generates, the high-frequency circuit of optical transmitter, particularly digital-to-analogue conversion portion (for example, be equivalent to Fig. 2 described later 116,116-1) be required the ultrahigh speed action.This is first problem.If more specifically narration then can generate the baseband OFDM signal with the speed of 2B originally, need be under the situation of signal but generate with the speed action of 4B comprising carrier wave.

Second problem is that the frequency band of receiver also is required broadband.With the signal demodulation, need have more boundary belt B, wide band photoelectric conversion part for the photoelectric current that receives Fig. 4.And then analog digital converter section (be equivalent to Figure 11 described later 221) also need be with the circuit of ultrahigh speed action.The electronic circuit of general high speed motion is very expensive, and perhaps under the poorest situation, promptly will be difficult to obtain under the too high situation of the bit rate that will realize, system can not realize.

Proposed one for first problem, be the solution countermeasure (non-patent literature 1) of the broad in band of optical transmitter (particularly digital-to-analogue conversion portion), it is the method for carrier wave being carried out addition after the generation of baseband OFDM signal.

The technology that non-patent literature 1 is recorded and narrated is for fear of first problem, is the technology of high speed of the digital-to-analogue conversion portion of optical transmitter.For second problem, be that particularly photoelectric conversion part or the broad in band of analog digital converter section and the countermeasure of high speed still are unresolved to optical receiver.

Summary of the invention

The present invention makes in view of above problem, and purpose provides a kind of not influence of interfering of acceptor intercarrier beat and then do not make the frequency band broad in band of optical receiver and optical communication system, optical transmitter and the transponder realized in the light ofdm communication system.

Be used to solve the means of problem

In the present invention, alternately send the light ofdm signal of different frequency spectrums, after this light is transmitted with optical fiber, carry out opto-electronic conversion with delay interferometer that equals 1 symbol time time of delay and balanced type direct detection receiver according to the symbol time of each OFDM.

Below, more specifically record and narrate with the means that solve problem.Also in execution mode, illustrate about each figure, below suitably reference.

Use Fig. 1 that the present invention is described.In optical communication system of the present invention, optical transmitter 100 is connected with optical receiver 200 usefulness optical fiber 300.In the transmission signal processing part 110 of optical transmitter 100 inside, will be converted to the baseband OFDM signal from the data that will communicate by letter of input input.Here, the structure example of transmission signal processing part in this way as shown in Figure 2.

The real part and the imaginary part of baseband OFDM signal are converted to the light ofdm signal with electric light converter section 120, send to optical fiber 300.This light ofdm signal is alternately got two kinds of frequency spectrums shown in Figure 7 according to each OFDM symbol time as shown in Figure 6.

This light ofdm signal behind the process optical fiber 300 is to optical receiver 200 incidents.Optical receiver 200 possesses time of delay T and equals delay interferometer 230, balanced type photoelectric conversion part 210 and the received signal handling part 220 of 1 symbol time of OFDM.Light ofdm signal after will interfering by the light signal before

delay interferometer

230 and 1 symbol time is converted to the signal of telecommunication with balanced type photoelectric conversion part 210, this signal of telecommunication is demodulated into as the data of information with received signal handling part 220 also exports.

The structure of expression delay interferometer in Fig. 8, the structure of expression balanced type photoelectric conversion part in Fig. 9, the structure example of expression received signal handling part in Figure 11.

Then, in the structure of this optical transmitter and optical receiver, do not have the influence that beat is interfered between subcarrier, the frequency band of optical receiver is rendered as than mode was narrow in the past.Optical electric field E(t with the frequency spectrum of Fig. 7) represents with following formula.

［ numerical expression 1 ］ E (t)=E _C(t)+E _S(t) (1)

Here, E _C(t) electric field of expression carrier wave, E _S(t) electric field of expression ofdm signal.As shown in Figure 7, the light frequency of the ofdm signal that is made of light frequency and a plurality of subcarrier of carrier wave alternately changes according to each code element.This optical electric field E(t) process optical fiber 300 is to delay interferometer 230 incidents.From the output port 1 of delay interferometer 230 and 2(with reference to Fig. 8) optical electric field represent with following formula respectively.

［ numerical expression 2 ］

E _portl(t)∝E(t)+E(t+T)

E _port2(t)∝E(t)-E(t+T)、 (2)

Here, T represent delay interferometer 230 time of delay, be the symbol time of OFDM.

These light are balanced type photoelectric conversion part 210 and are converted to the signal of telecommunication, and the ammeter that flows to respectively in two photodiodes of balanced type photoelectric conversion part 210 is shown numerical expression 3

［ numerical expression 3 ］

i ₁(t）∝|E _port1(t)| ²

i ₂(t)∝|E _port2(t)| ²、 (3)

As a result, the output V(t of balanced type photoelectric conversion part 210) become following formula.

［ numerical expression 4 ］

V (t) &Proportional; i_{1} (t) - i_{2} (t) &Proportional; E (t) \cdot E^{*} (t + T) + E^{*} (t) \cdot E (t + T) =

E_{C} (t) \cdot E_{C}^{*} (t + T) + E_{C}^{*} (t) \cdot E_{S} (t + T) + E_{C}^{*} (t + T) \cdot E_{S} (t) + E_{S} (t) \cdot E_{S}^{*} (t + T) + cc - - - (4)

The Beat Signal of the 1st the expression intercarrier on formula (4) the right, the Beat Signal (signal of hope) of the 2nd and the 3rd expression carrier wave and ofdm signal, the 4th represent between ofdm signal Beat Signal, be Beat Signal between subcarrier.

Here, in the signal of Fig. 6, constantly the code element of t is code element No.2, the code element of t+T is that the situation of code element No.1 describes constantly.Observe frequency spectrum (Fig. 7), the frequency (f of the carrier wave 1 of code element No.1 _LD1-f _S1) with the low-limit frequency (f of the ofdm signal of code element No.2 _LD2-B/2) difference is set at the frequency Δ f between subcarrier.Equally, the frequency (f of the carrier wave 2 of code element No.2 _LD2+ f _S2) with the low-limit frequency (f of the ofdm signal of code element No.1 _LD1-B/2) difference is set at the frequency Δ f between subcarrier.Here, B represents the frequency bandwidth of ofdm signal.And then, the band width W of boundary belt ₂Be at least more than the B.

If the frequency spectrum of the output signal of calculated equilibrium type photoelectric conversion part under above condition (formula (4)), then its result is Figure 10 (a).In the figure, the signal of white circle be ofdm signal S1 and S2 and (the 2nd of formula (4) the right with the 3rd and), Beat Signal between the subcarrier of black signal indication ofdm signal S1 that encloses and S2 (on the right of the formula (4) the 4th).

Then, if in the signal of Fig. 6, constantly the code element of t is code element No.3, the code element of t+T is that the situation of code element No.2 is calculated frequency spectrum equally constantly, then obtains Figure 10 (b).

According to Figure 10 (a) and two following as can be known situations of Figure 10 (b).At first, the signal of Beat Signal and hope between subcarrier (be in the case S1 and S2 and, perhaps S2 and S3 with) on frequency axis, separated fully, the Signal Degrade that brings because of interference does not take place.And then, with mode (with reference to Fig. 4) was different in the past, the lower frequency side of the signal distributions of hope Beat Signal between subcarrier, thereby the simulation frequency acceptance band that optical receiver 200 requires become in the past half, be approximately B.As a result, the required sample rate of analog-to-digital conversion circuit 221 also becomes half about 2B in the past.

In addition, in above-mentioned record, be the band width W of boundary belt ₂For the situation of the minimum value B that beat between subcarrier interferes does not take place fully, even but how much allow the Signal Degrade that generation brings because of interference, also need to satisfy numerical expression 5.

［ numerical expression 5 ］

W ₂＞B/2、 (5)

The output signal of telecommunication of balanced type photoelectric conversion part 210 enters into received signal handling part 220.The functional block diagram of expression received signal handling part 220 in Figure 11.The output signal of telecommunication of balanced type photoelectric conversion part 210 is at first at received signals handling part 220(Figure 11) analog-to-digital conversion circuit 221 be converted to digital signal after, Cyclic Prefix (cyclic prefix) is removed by (CPR) portion of removing by Cyclic Prefix, this signal is converted to parallel data with the parallel converter section 223 of serial, this parallel data is converted to each subcarrier with FFT portion 224.Since each subcarrier time that is used in go up for two code elements of front and back and (in Figure 10, be S1+S2 or S2+S3) data-modulated, so, implement the calculus of differences that constitutes by differential amplifier 227 and the delay circuit 228 that postpones 1 symbol time T for it is removed.This implements for following purpose, that is: in each symbol time be S1+S2, S2+S3, S3+S4 ... same symbol occurs in time in succession like this, thus to change by this calculus of differences so that in each symbol time be S1, S2, S3, S4 ... the purpose that such each code element only occurs is once implemented.Then, carry out handling identical process with the received signal of in the past ofdm signal.That is, by subcarrier demodulation portion according to each subcarrier with data demodulates, their parallel data is reverted to serial data with parallel serial conversion portion 226, export as data.

It more than is elemental motion principle of the present invention.Can realize as original purpose of the present invention avoid beat between subcarrier to interfere and the analog frequency band of receiver is in the past half light ofdm communication system.

According to the 1st technical scheme of the present invention, a kind of optical communication system is provided, the lasting symbol time of optical transmitter maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates, send with light signal via optical fiber, optical receiver will be propagated the light signal that comes and carry out opto-electronic conversion in this optical fiber, original numerical data is reproduced in each sub-carrier signal demodulation, above-mentioned optical transmitter possesses: send signal processing part, lasting symbol time maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates, and generates the baseband OFDM signal according to the sub-carrier signal after the modulation; The electric light converter section is modulated to laser with this baseband OFDM signal, generates the light ofdm signal; Alternately send wavelength different light ofdm signal with above-mentioned electric light converter section according to symbol time by above-mentioned transmission signal processing part; Above-mentioned optical receiver has: make the part of the light ofdm signal that receives from above-mentioned optical transmitter via optical fiber postpone symbol time and with the synthetic delayed interference portion of light ofdm signal and the light signal after will synthesizing be converted at least one group of the balanced type photoelectric conversion part of the signal of telecommunication; The received signal handling part obtains sub-carrier signal from the output of above-mentioned photoelectric conversion part, with data demodulates, reproduces original numerical data according to this sub-carrier signal.

According to the 2nd technical scheme of the present invention, a kind of optical transmitter is provided, be that optical transmitter continues symbol time and numerical data is mapped to mutually orthogonal a plurality of subcarriers and modulates and send with light signal via optical fiber, optical receiver will be propagated the light signal that comes and carry out opto-electronic conversion in this optical fiber, each sub-carrier signal demodulation is reproduced the above-mentioned optical transmitter in the optical communication system of original numerical data, possess: send signal processing part, lasting symbol time maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates, and generates the baseband OFDM signal according to the sub-carrier signal after the modulation; The electric light converter section is modulated to laser with this baseband OFDM signal, generates the light ofdm signal; Alternately send wavelength different light ofdm signal with above-mentioned electric light converter section according to symbol time by above-mentioned transmission signal processing part.

According to the 3rd technical scheme of the present invention, a kind of transponder is provided, be that optical transmitter continues symbol time and numerical data is mapped to mutually orthogonal a plurality of subcarriers and modulates and carry out opto-electronic conversion, each sub-carrier signal demodulation reproduced the transponder in the optical communication system of original numerical data with the light signal that light signal sends, optical receiver will be propagated in this optical fiber via optical fiber, possess above-mentioned optical transmitter and above-mentioned optical receiver; Above-mentioned optical transmitter possesses: send signal processing part, lasting symbol time maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates, and generates the baseband OFDM signal according to the sub-carrier signal after the modulation; The electric light converter section is modulated to laser with this baseband OFDM signal, generates the light ofdm signal; Alternately send the light ofdm signal of 2 different wavelength of wavelength according to symbol time by above-mentioned transmission signal processing part and above-mentioned electric light converter section; Above-mentioned optical receiver has: make the part of the light ofdm signal that receives from above-mentioned optical transmitter via optical fiber postpone symbol time and with the synthetic delayed interference portion of light ofdm signal and the light signal after will synthesizing be converted at least one group of the balanced type photoelectric conversion part of the signal of telecommunication; The received signal handling part obtains sub-carrier signal from the output of above-mentioned photoelectric conversion part, with data demodulates, reproduces original numerical data according to this sub-carrier signal.

The invention effect

According to the present invention, in the light ofdm communication system, the influence that acceptor intercarrier beat not interferes can be provided and then can not make the frequency band broad in band of optical receiver and optical communication system, optical transmitter and the transponder realized.

Description of drawings

Fig. 1 is the functional block diagram of smooth ofdm communication system of the present invention.

Fig. 2 is the functional block diagram that sends signal processing part.

Fig. 3 is the schematic diagram of frequency spectrum of the light ofdm signal light of light ofdm communication system in the past.

Fig. 4 is the schematic diagram of frequency spectrum of the reception signal of telecommunication of light ofdm communication system in the past.

Fig. 5 is the key diagram of the functional block diagram of electric light converter section.

Fig. 6 is the seasonal effect in time series schematic diagram of explanation smooth ofdm signal of the present invention.

Fig. 7 is the schematic diagram of an example of the frequency spectrum of explanation smooth ofdm signal light of the present invention.

Fig. 8 is the structure chart of delayed interference portion.

Fig. 9 is the structure chart of balanced type photoelectric conversion part.

Figure 10 is the schematic diagram of an example of the frequency spectrum of the explanation reception signal of telecommunication of the present invention.

Figure 11 is the functional block diagram of the received signal handling part of the 1st execution mode of the present invention.

Figure 12 is the structure chart of the electric light converter section of the 1st execution mode of the present invention.

Figure 13 is the structure chart of the electric light converter section of the 2nd execution mode of the present invention.

Figure 14 is the schematic diagram of frequency spectrum of the transmissison characteristic of the filter that uses with the 2nd electric light converter section of the present invention of explanation.

Figure 15 is the functional block diagram of the transmission signal processing part of the 3rd execution mode of the present invention.

Figure 16 is the structure chart of the electric light converter section of the 3rd execution mode of the present invention.

Figure 17 is the spectral schematic diagram in each one of electric light converter section of the 3rd execution mode of the present invention.

Figure 18 is the seasonal effect in time series schematic diagram of the light ofdm signal of explanation the 3rd execution mode of the present invention.

Figure 19 is the schematic diagram of frequency spectrum of the light ofdm signal light of explanation the 3rd execution mode of the present invention.

Figure 20 is the functional block diagram of the optical receiver of the 4th execution mode of the present invention.

The schematic diagram of the frequency spectrum of the transmissison characteristic of Figure 21 filter that to be explanation use with the optical receiver of the 4th execution mode of the present invention.

Figure 22 is the schematic diagram of frequency spectrum of the reception signal of telecommunication of the optical receiver of the 4th execution mode of the present invention.

Figure 23 is the functional block diagram of received signal handling part of the optical receiver of the 4th execution mode of the present invention.

Embodiment

Below, present embodiment is described.

1. the 1st execution mode

Wait explanation the 1st execution mode with reference to Fig. 1.Here, the modulation for explanation with subcarrier is assumed to 4-QAM, but present embodiment is not restricted to this, can adopt subcarrier modulation modes arbitrarily.In addition, the bar number of subcarrier is assumed to be N bar (N is an integer).

The structure chart of the light ofdm communication system of expression present embodiment in Fig. 1.

The light ofdm communication system for example possesses optical transmitter 100, optical fiber 300 and optical receiver 200.Optical transmitter 100 for example has the signal processing part 110 of transmission and electric light converter section 120.Optical receiver 200 has delay interferometer 230, balanced type photoelectric conversion part 210 and received signal handling part 220.Optical transmitter 100 is connected via optical fiber 300 with optical receiver 200.

If the numerical data that will communicate by letter was input in the optical transmitter 100 originally, then be converted to the baseband OFDM signal by the transmission signal processing part 110 of the inside of optical transmitter 100, this signal is converted to the light ofdm signal by electric light converter section 120.This light ofdm signal arrives direct detection optical receiver 200 through the optical fiber 300 as transfer path.The light ofdm signal is received and is converted to the signal of telecommunication by photoelectric conversion part 210 direct detections.This signal of telecommunication is above-mentioned baseband OFDM signal ideally, and this signal received signals handling part 220 is demodulated into numerical data and the output that will communicate by letter originally.

Fig. 2 represents the functional block diagram of the transmission signal processing part 110 of the 1st execution mode.

Send signal processing part 110 and for example possess parallel (S/P) converter section 111 of serial, subcarrier-modulated portion 112, contrary FFT portion (contrary fast fourier transform portion) 113, parallel serial (P/S) converter section 114 and digital simulation (D/A) converter section 116,116-1.In addition, also can Cyclic Prefix be set between P/S converter section 114 and D/A converter section 116,116-1 and insert (CPI) portion 115, pended cyclic prefix.

Originally the data that will communicate by letter were converted to 2N parallel data by S/P converter section 111.Here, N is the bar number that carries the subcarrier of data.Be 2N parallel data under the situation that is modulated at 4-QAM of subcarrier, but for example be 4N under the situation of 16-QAM.That is, serial data is converted to " the bar number of the bit number * subcarrier of 1 code element " individual parallel data.Subcarrier-modulated portion 112 uses this parallel data that N bar subcarrier is modulated.Subcarrier (C after this modulation _k, k=0,1 ... N-1) be imported in the contrary FFT portion 113.The signal of input is converted to the data of time shaft by contrary FFT portion (contrary fast fourier transform portion) 113, is converted to serial data by P/S converter section 114.The real part of this serial data and imaginary part are converted into analog signal and output through D/A converter section 116 and 116-1 respectively.The signal of this output is called the baseband OFDM signal.

Before the structure and action of the electric light converter section 120 that present embodiment is described, the example of electric light converter section shown in Figure 5 is described as the auxiliary of understanding at first.Will be as the real part of the baseband OFDM signal of the output signal of the D/A converter section 116 that sends signal processing part 110,116-1 and imaginary part adds RF oscillator 123 respectively in adder 125 and 125-1 output RF signal (frequency f _s) cosine wave (cos component) and sinusoidal wave (sin component.Because the phase place of cosine wave is offsetted 90 °, so also can generate through phase shifter 124), and be applied to respectively on the I port and Q port of light I-Q modulator 122.Light I-Q modulator 122 is known for example to be had and utilizes at LiNbO ₃The equipment of the electric optical effect in the fiber waveguide that is made on (lithium niobate) substrate, but be not limited thereto, for example also can be the equipment that on the InP substrate, is made into.

Laser (light source) 121 sends light frequency f _LDLight, this light incides in the light I-Q modulator 122.In light I-Q modulator 122, with the I component of this light with the signal of telecommunication modulation that is input in the I port, with the Q component of light with the signal of telecommunication modulation that is input in the Q port, with these two components, be the modulated I component light and Q component light mutually adduction export.The frequency spectrum of the output light of light I-Q modulator 122 (below be called the light ofdm signal) is with light frequency f _LDBe the center, by as the ofdm signal of the set of a plurality of subcarriers with by frequency f _SThe lower sideband wave component of the light that generates of RF signal (frequency is f _LD-f _SBelow being called carrier wave) (carrier wave also can be upper side band wave component f to formation certainly _LD+ f _S).Here, f _SIf establishing the frequency band of baseband OFDM signal is B, the boundary belt width of establishing hope is W, then for example is set at W+B/2.So the frequency spectrum of the output light of the light I-Q modulator 122 under this situation is Fig. 3 (being W ≒ B in Fig. 3).Based on this example, structure and its action of the electric light converter section of present embodiment are described then.

The structure of the electric light converter section of expression first execution mode of the present invention in Figure 12.

Will be as the real part of the baseband OFDM signal of the output that sends signal processing part 110 and cos component and the sin component that imaginary part adds the RF signal respectively, it is applied on the I-port and Q-port of light I-Q modulator 122, is identical to the elemental motion of being modulated from the light of laser 121-1 with above-mentioned example.

The point different with above-mentioned example, at first be by RF oscillator 126 control from the light of laser 121-1 so that its each symbol time according to ofdm signal is alternately chosen two different light frequency f _LD1And f _LD2Certain this point.The switching of this light frequency for example can realize laser 121-1 and make this semiconductor laser with semiconductor laser drive current changes slightly according to the output signal of RF oscillator 126 to be realized.In addition, with two optical frequency rate variance f _LD1-f _LD2(be assumed to f _LD1F _LD2) be set at and how much will narrate in the back.Being not limited to this, also can be the light source portion that produces the light of two light frequencies by additive method.

In addition, (frequency of oscillation separately is f to the RF signal that the real part and the imaginary part of baseband OFDM signal added with the output of two RF oscillator 123-1 and 123-2 _S1And f _S2) a certain side's output select this point also different with 2x1 electric switch 127-1 and 127-2 with above-mentioned example.And then the component sine waves of the output separately of RF oscillator 123-1 and 123-2 differ 180 ° of phase places mutually and (are antiphase.In addition, cosine component is a same-phase).This can be set at-90 ° and+90 ° by the setting with phase shifter 124-1 and 124-2 respectively and realizes.In addition, also can be to produce the component sine waves of two frequencies and the oscillating portion of cosine wave component respectively by additive method.

The switching of 2x1 electric switch 127-1 and 127-2 is carried out synchronously according to each symbol time of ofdm signal.In addition, switch also with the switching according to each symbol time (being subjected to 126 controls of RF oscillator) of the light frequency of above-mentioned laser 121-1 synchronously.And then, should be according to the switching and the clock synchronization that sends signal processing part 110 of each symbol time.That is, whole logical circuit of optical transmitter 100, oscillator, diverter switch are got by identical clock synchronously.

The light ofdm signal (being the output light of light I-Q modulator 122) of this moment can schematically be represented as shown in Figure 6.That is, the light frequency from laser 121-1 of certain code element (supposing to be called code element No.1) is f _LD1, the frequency of the RF signal that the baseband OFDM signal is added is f _S1The light frequency from laser 121-1 of its next code element No.2 is f _LD2, the frequency of the RF signal that the baseband OFDM signal is added is f _S2Again then its code element, be code element No.3,5 ... use the light frequency f identical with code element No.1 _LD1With RF signal frequency f _S1, code element No.4,6 ... use the light frequency f identical with code element No.2 _LD2With RF signal frequency f _S2

In addition, as narrating, because the sinusoidal component of two RF signals opposite phase each other mutually, so frequency of utilization is f _S1The code element No.1,3,5 that generates of RF signal ... carrier wave be the lower sideband ripple, frequency of utilization is f _S2The code element No.2,4,6 that generates of RF signal ... carrier wave be upper side band wave.And then, if with the frequency f of RF signal _S1And f _S2For example be set at different values as described later, then the frequency spectrum of light ofdm signal can be such for Fig. 7.The figure of the top of Fig. 7 be code element No.1,3,5 ... the time frequency spectrum, the figure of the below of Fig. 7 be code element No.2,4,6 ... the time frequency spectrum.

Frequency f as the RF signal of the output of RF oscillator 123-1 and 123-2 _S1And f _S2For example decision as follows.That is be W, if establish the frequency bandwidth of boundary belt ₁And W ₂, the frequency band of establishing ofdm signal is B, then can be by numerical expression 6

［ numerical expression 6 ］

f_{S 1} = W_{1} + \frac{B}{2}

f_{S 2} = W_{2} + \frac{B}{2} \cdot - - - (6)

Provide (with reference to Fig. 7).The frequency bandwidth W of boundary belt ₁And W ₂Set narrowly as far as possible for the spectrum utilization efficiency that improves light, on the other hand, the interference that Beat Signal brings between the subcarrier that takes place for fear of by direct detection the time and need set broad.

At (under the situation of Figure 10) under the situation of the interference that the Beat Signal of avoiding factor intercarrier fully brings, the frequency bandwidth W of boundary belt ₁And W ₂Minimum value be respectively about 2B and B.More correctly say, need satisfy numerical expression 7

［ numerical expression 7 ］

W ₁≥W ₂+B+2·Δf

W ₂≥B、 (7)

Relation.Here, Δ f represents the frequency interval between subcarrier, and numerical expression 8 is arranged

［ numerical expression 8 ］

B=(N one l) Δ f, (8)

Relation.

The optical frequency rate variance f of laser _LD1-f _LD2According to Fig. 7 and Shi (7), provide by following formula.

［ numerical expression 9 ］

f _LD1-f _LD2＝B+W ₂+Δf≥2B+Δf、（9)

In addition, under the situation of the interference that the Beat Signal that can not avoid factor intercarrier fully brings, be the frequency bandwidth W that how many tolerance factor intercarrier beats are interfered the boundary belt under the situation of the signal quality deterioration of bringing ₁And W ₂At least need to be respectively about 3B/2 and more than the B/2.In the case, the subcarrier of the high frequency side in the ofdm signal that the receives pact of subcarriers (all half) is subjected to the influence that beat is interfered between subcarrier, the influence that the subcarrier of all the other half lower frequency side is not interfered is the state that does not have the deterioration of received signal quality.

In description of the present embodiment, about the situation of two conditions of the minimum value that satisfies formula (6) and formula (7), promptly avoid the situation of the interference that the Beat Signal of factor intercarrier brings fully, below go on to say.Frequency spectrum under this situation is as shown in Figure 7.That is, code element No.1,3 ... carrier wave 1 and code element No.2,4 ... ofdm signal in the frequency interval of low-limit frequency side subcarrier be Δ f.Equally, code element No.2,4 ... carrier wave 2 and code element No.1,3 ... ofdm signal in the frequency interval of low-limit frequency side subcarrier be Δ f.

The light ofdm signal that is generated by above-mentioned electric light converter section 120 is as the transmission light of optical transmitter 100, and transmission in as the optical fiber 300 of transfer path arrives optical receiver 200.In optical receiver 200, at first incide in the delay interferometer 230.

The structure of expression delay interferometer 230 in Fig. 8.Be separated into two light from the light of the input port incident of delay interferometer 230 by optical coupler 231, one is delayed after the time, portion 233 postponed the 1 symbol time T of OFDM, synthesized by optical coupler 232 with another light after separating, from output port 1 and output port 2 outputs.

The concrete structure of expression balanced type photoelectric conversion part 210 in Fig. 9.Be balanced type photoelectric conversion part 210 from the light of two output ports of delay interferometer 230 and be converted to the signal of telecommunication.The balanced type photoelectric conversion part for example is made of two photodiodes and preamplifier, will be carried out subtraction from two signals that light is converted to electric current by photodiode, from 210 outputs of balanced type photoelectric conversion part.

The frequency spectrum of the output signal of expression balanced type photoelectric conversion part 210 in Figure 10.Figure 10 (a) be with the code element No.1 of the light ofdm signal of Fig. 6 and code element No.2 with the frequency spectrum under the synthetic situation of delayed interference portion 230, Figure 10 (b) is with the frequency spectrum under the synthetic situation of delayed interference portion 230 with the code element No.2 of the light ofdm signal of Fig. 6 and code element No.3.This Figure 10 is the situation of light ofdm signal of two conditions that satisfies the minimum value of formula (6) and formula (7).

According to Figure 10 as can be known, can access at lower frequency side the ofdm signal that will receive and (S1+S2, S2+S3 ...), can access the Beat Signal between the subcarrier of different symbol times at high frequency side.If satisfy two conditions of formula (6) and formula (7), then Beat Signal can separate on frequency spectrum fully between ofdm signal and subcarrier.And then, with mode (with reference to Fig. 4) was different in the past, present desired ofdm signal at lower frequency side, Beat Signal appears at high frequency side between unwanted subcarrier, so the analog component of optical receiver 200 is enough about photodiode, preamplifier, the frequency bandwidth B of the needed frequency band of A/D converter with ofdm signal for example.

The functional block diagram of expression received signal handling part 220 in Figure 11.The output signal of balanced type photoelectric conversion part 210 is input in the received signal handling part 220.The output signal of photoelectric conversion part 210-1 simulated 221 digitlizations of numeral (A/D) converter section, is recycled prefix and removes (CPR) portion 222 removal Cyclic Prefix, is converted to N bar parallel data by parallel (S/P) converter section 223 of serial.These parallel datas are in the FFT(fast fourier transform) be separated into N bar sub-carrier signal in the portion 224.Then, will carry data demodulates in each subcarrier, be converted to serial data, as receiving information data output by parallel serial (P/S) converter section 226 by subcarrier demodulation portion 225.

In the received signal handling part 220 of present embodiment, after being separated into each subcarrier, the signal before its signal and 1 code element is asked poor, to demodulation section 225 transmission of next stage by FFT portion 224.Particularly, each subcarrier of the output of FFT portion 224 is imported among differential amplifier 227, the 227-1.The output of this differential amplifier is delayed the 1 symbol time T of circuit 228,228-1 delay OFDM, is connected in another input of differential amplifier 227,227-1.Thereby, export the poor of the signal of current code element and the signal before 1 symbol time by this differential amplifier 227,227-1.

As explanation among Figure 10, the effect of the sub-carrier signal that receives by delay interferometer 230 become two continuous code elements and, if so such delay circuit and differential amplifier are used according to each subcarrier, then in the output of each differential amplifier, can access the signal (S1 of each code element, S2, S3 ...).

The output of differential amplifier 227,227-1 is as described above by 225 demodulation of subcarrier demodulation portion, and the parallel serial conversion portion of being followed 226 is converted to serial data, as the output signal output of optical receiver 200.This is the data that receive.

2. the 2nd execution mode

Use Figure 13 that the 2nd execution mode is described.In the present embodiment, electric light converter section 120 is different with the 1st execution mode, and other parts are all identical with the 1st execution mode, and it illustrates omission.

Figure 13 is the functional block of electric light converter section 120 of expression the 2nd execution mode and the figure of filter 130.

As the real part of the baseband OFDM signal of the output that sends signal processing part 110, in adder 125 by with select by 2x1 switch 127 as frequency f _S1RF oscillator 123-1 or frequency f _S2Cosine wave (COS) addition of output of RF oscillator 123-2, be applied on the I port of light I-Q modulator 122.On the other hand, the imaginary part of baseband OFDM signal is applied on the Q port of light I-Q modulator 122 by former state.The only light frequency that incides in the light I-Q modulator 122 alternately is changed to f according to each OFDM symbol time _LD1And f _LD2Light, the light that this only penetrates from laser 121-1.Laser 121-1 for example can be realized by semiconductor laser, in the case, changes slightly according to each OFDM symbol time corresponding to the output of RF oscillator 126 by the drive current that makes semiconductor laser, light frequency can be switched to f _LD1And f _LD2

In addition, the switching timing of above-mentioned 2x1 switch 127 and carry out synchronously from the switching (it is subjected to 126 controls of RF oscillator) of the light frequency of laser also each symbol time according to ofdm signal.And then, should be according to the switching and the clock synchronization that sends signal processing part 110 of each symbol time.That is, whole logical circuit of optical transmitter 100, oscillator, diverter switch are got with identical clock synchronously.

In the electric light converter section 120 of present embodiment, same with the electric light converter section of the 1st execution mode, according to each OFDM symbol time, (frequency is f to the RF signal _S1Or f _S2) and light frequency (f _LD1And f _LD2) switch.The frequency bandwidth W of this RF signal, light frequency and boundary belt ₁And W ₂Relation also identical with the 1st execution mode.

The points different with the 1st execution mode are that (frequency is f owing to the RF signal _S1Or f _S2) be applied only on the I port of light I-Q modulator, so there is the ofdm signal that is made of a plurality of subcarriers in the frequency spectrum of the output light of this electric light converter section 120 and the carrier wave that generates by above-mentioned RF signal at its high frequency side and lower frequency side (in the 1st execution mode, carrier wave only is illustrated in the high frequency side or the lower frequency side of ofdm signal.With reference to Fig. 7).

Make the light of the electric light converter section 120 of present embodiment pass through filter 130.Figure 14 represents the frequency spectrum of the output light of the transmissison characteristic of filter 130 and this filter 130.Filter is a band pass filter, is set to, and will be in the carrier wave (frequency f of the both sides of ofdm signal _LD1± f _S1And f _LD2± f _S2) a side block.For example, to major general's frequency f _LD1+ f _S1(in Figure 14, the carrier wave (not shown) that in the figure of upside, occurs) and frequency f at the high frequency side of ofdm signal _LD2-f _S2(in Figure 14, the carrier wave (not shown) that occurs at the lower frequency side of ofdm signal in the figure of downside) blocks.As a result, the frequency spectrum of the output light of filter 130 as shown in Figure 14, the OFDM code element be No.1, No.3 ... the time by the carrier wave (frequency f of lower frequency side _LD1-f _S1) and ofdm signal S1, S3 ... constitute, the OFDM code element be No.2, No.4 ... the time by the carrier wave (frequency f of high frequency side _LD2+ f _S2) and ofdm signal S2, S4 ... constitute.

In addition, filter 130 for example can be by the light Comb for dividing waves device realizations such as (interleaver) that forms by the filter of dielectric multilayer film formation, by fiber waveguide.And then this filter under the situation in carrying each optical transmitter 100 separately, also can use the so-called wave multiplexer realization with the photosynthetic ripple of output of each optical transmitter 100 under the situation of wavelength multiplexing system.In the case, wave multiplexer can pass through so-called AWG(Arrayed Waveguide Grating, array waveguide grating) realize.

According to above description of the present embodiment as can be known, as the light ofdm signal in the optical fiber of transfer path, be the output light of filter 130, be the light identical with the light of the 1st execution mode.Thereby the effect of the structure of optical receiver 200 and Qi Ge portion is identical with the 1st execution mode, and detailed explanation is omitted.

It more than is the explanation of the 2nd execution mode.In addition, in the present embodiment, the structure of transmitter simply is one of feature than the 1st execution mode.

3. the 3rd execution mode

Use Figure 15～Figure 18 to wait explanation the 3rd execution mode.

In the present embodiment, baseband OFDM signal and RF signal are passed through the Digital Signal Processing addition.

Optical transmitter 100 connects identical with the 1st execution mode with optical receiver 200 via the optical fiber 300 as transfer path.

Expression sends the functional block diagram of signal processing part 110-2 in Figure 15.In optical transmitter 100, the data that will send are converted to the baseband OFDM signal by sending signal processing part 110-2.The numerical data that sends and first execution mode and second execution mode are carried out signal processing equally, 115 outputs from the Cyclic Prefix insertion section.This output is corresponding to the real part and the imaginary part of baseband OFDM signal.These outputs are by 1x2 electric switch 117-1 and 117-2.This 1x2 electric switch 117-1 and 117-2 alternately switch two outputs according to each OFDM symbol time T respectively.The switching of the switching timing of this switch and OFDM code element is synchronous.Thereby, OFDM code element No.1, No.3 ... output and code element No.2, No.4 ... the output difference.The real part of baseband OFDM signal in these outputs in adder 125,125-2 by with the frequency f of the inside that sends signal processing part _SCosine wave (cos) the output addition of RF oscillator 123-3, the imaginary part of ofdm signal in adder 125-1,125-3 by with sine wave (sin) the output addition of RF oscillator 123-3.Export with 4 digital-to-analogue conversion (A/D) circuit 116 adding the baseband OFDM signal behind the RF signal.In addition, the frequency f of RF oscillator 123-3 _SFor

f _S=B/2+Δf （10）

This setting is that to make spectrum width be minimum setting.Here, B is the frequency bandwidth of baseband OFDM signal, and Δ f is the frequency interval of subcarrier.

The method of addition in Digital Signal Processing also has beyond Figure 15 with baseband OFDM signal and RF signal.For example, also can be to add the port of the needed RF frequency ports of input of contrary FFT converter section 113 of Figure 15 and zero padding (zero padding) usefulness and carry out the method that contrary FFT changes.

4 output signals of transmission signal processing part 110-2 (baseband OFDM signal S1, S3 ... with the RF signal and real part and its imaginary part, and baseband OFDM signal S2, S4 ... with the RF signal and real part and its imaginary part) be guided among the electric light converter section 120-2 of Figure 16.

Electric light converter section 120-2 has laser 121 with fixed wave length vibration, its light is carried out modulated M ach-Zehnder optical modulator 128 and drives its RF oscillator 123-4,2 light I-Q modulator 122-1 and 122-2 being modulated respectively with the filter 129 of the light partial wave of the output of this optical modulator 128, to two light behind the partial wave and the filter 400 that their output is closed ripple.

Then, use Figure 17 that the action of this electric light converter section 120-2 is described.The frequency of oscillation of laser 121 is set to (f _LD1+ f _LD2)/2(Figure 17 (a) reference).Use common semiconductor laser as laser 121.The ejaculation light of this laser 121 is to 128 incidents of Mach-Zehnder optical modulator.This Mach-Zehnder optical modulator 128 is set at the extinction point of its transmissison characteristic with the bias current point, as drive signal and frequency of utilization (f _LD1-f _LD2The sinewave output of the RF oscillator 123-4 of)/2.At this moment, the frequency spectrum of the output light of Mach-Zehnder optical modulator 128 is Figure 17 (b).That is, this light has two spectrum component (frequency f _LD1And f _LD2).Make this light to filter 129 incidents.Two spectrum components that filter 129 will comprise in the output light of Mach-Zehnder optical modulator 128 separate, and penetrate to two output ports respectively.As this filter 129, practicability so-called smooth Comb for dividing waves device etc.In addition, light frequency f _LD1-f _LD2Setting follow formula (9) and (be assumed to f _LD1F _LD2).

Two outputs of filter 129 are respectively frequency f _LD1Light and frequency f _LD2Light.These light are modulated and output with light I-Q modulator 122-1 and 122-2 respectively.

The drive signal of light I-Q modulator 122-1 be baseband OFDM signal S1, S3 ... with RF signal (frequency f _S) and signal.Equally, the drive signal of light I-Q modulator 122-2 be baseband OFDM signal S2, S4 ... with the RF signal and signal.By electric switch 117-1,117-2 are switched according to each symbol time, each drive signal is alternately imported to light I-Q modulator 122-1,122-2 according to each symbol time.In addition, beyond electric switch 117-1,117-2, also can be with suitable method to light I-Q modulator input drive signal alternately.

The frequency spectrum of light I-Q modulator 122-1 that expression is driven by these signals and the output light of 122-2 be Figure 17 (c)～Figure 17 (f).Promptly, the OFDM code element that Figure 17 (c) is illustrated in the output light of light I-Q modulator 122-1 be No.1, No.3 ... the time frequency spectrum, the OFDM code element that Figure 17 (d) is illustrated in the output light of light I-Q modulator 122-1 be No.2, No.4 ... the time frequency spectrum, the OFDM code element that Figure 17 (e) is illustrated in the output light of light I-Q modulator 122-2 be No.1, No.3 ... the time frequency spectrum, the OFDM code element that Figure 17 (f) is illustrated in the output light of light I-Q modulator 122-2 be No.2, No.4 ... the time frequency spectrum.Here, illustrate the situation that formula (10) is set up.

The output light of two light I-Q modulator 122-1 and 122-2 is closed ripple by filter 400, and the output light that this light is used as optical transmitter 100 sends to the optical fiber 300 as transfer path.

As filter 400, both can be the light Comb for dividing waves device same with above-mentioned filter 129, also can be simple optical coupler.

The light signal that transmission comes in optical fiber 300 is to optical receiver 200 incidents.This optical receiver is the optical receiver 200 that uses in the 1st execution mode or the 2nd execution mode.

It more than is the 3rd execution mode.

In addition, the output light of the filter 400 of present embodiment, be that the frequency spectrum of the output light of optical transmitter 100 is Figure 19.Compare Figure 19 and Fig. 7 as can be known, the carrier wave of the frequency spectrum of present embodiment has increased.That is, code element No.1, No.3 ... the carrier wave 2 in the moment and code element No.2, No.4 ... the carrier wave 1 in the moment.These unnecessary carrier waves generate unnecessary signal in optical receiver, promptly code element No.1, No.3 ... the moment carrier wave 2 and code element No.2, No.4 ... the moment ofdm signal S2, S4 ... Beat Signal, also have code element No.2, No.4 ... the moment carrier wave 1 and code element No.1, No.3 ... the moment ofdm signal S1, S3 ... Beat Signal.But; these with the signal of wanting originally to receive, be code element No.1, No.3 ... the moment carrier wave 1 and code element No.2, No.4 ... the moment ofdm signal S2, S4 ... Beat Signal and code element No.2, No.4 ... the moment carrier wave 2 and code element No.1, No.3 ... the moment ofdm signal S1, S3 ... Beat Signal compare because the band width W of boundary belt is arranged ₂So, be present in high frequency side.Thereby, if with boundary belt W ₂Get ofdm signal frequency bandwidth B above (with reference to formula (7)), then these signals can separate on frequency spectrum with the signal of wanting originally to receive, and are no problem in reception.The output light of this filter 400 is schematically represented as Figure 18 on time shaft.As narrating, each OFDM code element is made of baseband OFDM signal and two carrier waves.The points different with the output (with reference to Fig. 6) of the optical transmitter 100 of first and second execution mode are always to have two carrier wave this point in each OFDM code element.

As the peculiar speciality of present embodiment be, because by sending the add operation that signal processing part 110-2 digitally carries out the RF signal, so need in optical transmitter 100, not prepare the RF oscillator, adder of physics or with the electric switch of high speed motion, thereby can realize with low cost, and then, do not need as the 1st or the 2nd execution mode, to use a plurality of electric switches to get synchronous switching, thereby control becomes simple etc.

4. the 4th execution mode

Below use Figure 20 to wait expression the 4th execution mode.1st, the output light of the optical transmitter 100 of the 2nd or the 3rd execution mode transmits in as the optical fiber 300 of transfer path, to optical receiver 200 incidents.

The structure of the optical receiver 200 of expression present embodiment in Figure 20.This optical receiver 200 has filter 240, two delay interferometer 230-1 and 230-2, their output is converted to the balanced type photoelectric conversion part 210-2 and the 210-3 of the signal of telecommunication and extract the received signal handling part 220-2 of data from their output.

The action of this optical receiver 200 then is described.Frequency spectrum to the light of optical receiver 200 incidents for example is as shown in Figure 19.Below, use the light ofdm signal explanation of the 3rd execution mode.This light is at first to filter 240 incidents.The frequency spectrum of the transmissison characteristic of expression filter 240 and input light in Figure 21.Figure 20's is solid line from input port (COM) to the transmissison characteristic of output port (A), is illustrated in Figure 21 with the single-point line from the transmissison characteristic of input port (COM) to output port (B).That is, carrier wave 1 is blocked in output port (A), and in output port (B), carrier wave 2 is blocked.For example, in output port (A) side, will compare f _LD2The frequency that+B/2 is low is blocked, and in output port (B) side, will compare f _LD1-f _SHigh frequency is blocked.

Thereby, the light of output port (A) code element No.1, No.3 ... the moment by carrier wave 2 and ofdm signal S1, S3 ... constitute, code element No.2, No.4 ... the moment constitute by carrier wave 2.Equally, the light of output port (B) code element No.1, No.3 ... the moment only constitute by carrier wave 1, code element No.2, No.4 ... the moment by ofdm signal S2, S4 ... constitute with carrier wave 1.

The light of port (A) and port (B) is respectively to delay interferometer 230-1 and 230-2 incident.Its output light is balanced type photoelectric conversion part 210-2 respectively and 210-3 is converted to the signal of telecommunication, is guided to received signal handling part 220-2.

In addition, with the frequency spectrum designation of the output signal of balanced type photoelectric conversion part 210-2 in Figure 22 (a).OFDM code element No.1, No.2, No.3, No.4 ... the signal that obtains of the moment be ofdm signal S1, S1, S3, S3 ..., repeat identical signal with two continuous code elements.The output signal of balanced type photoelectric conversion part 210-3 too, OFDM code element No.1, No.2, No.3, No.4 ... the signal that obtains of the moment be ofdm signal S2, S2, S4, S4 ..., repeat identical signal with two continuous code elements.

The functional block diagram of expression received signal handling part 220-2 in Figure 23.The output signal of balanced type photoelectric conversion part 210-2 and 210-3 simulated digital translation (A/D) 221-1 of portion respectively and 221-2 is converted to digital signal.This output is selected output by 2x1 electric switch 229 with two input signals according to the timing of OFDM code element.Thereby, its output code element No.1, No.2, No.3, No.4 ... the moment can access ofdm signal S1, S2, S3, S4 ... the signal of hope.

The output of this 2x1 electric switch 229 is accepted and routine same acknowledge(ment) signal processing in the past then, is exported from optical receiver 200 as receiving data.

It more than is description of the present embodiment.

In addition, above description of the present embodiment uses the light ofdm signal from the transmitter 100 of the 3rd execution mode to carry out, but optical receiver 200 is for also being suitable in the light of the optical transmitter 100 that uses in the 1st and the 2nd execution mode (its frequency spectrum for as shown in Figure 7).

The peculiar speciality of present embodiment is, can be with the width W of boundary belt ₂The gradient (with reference to Figure 21) decision with the transmissison characteristic of filter 240.Promptly under the situation of the rapider filter 240 of the width that uses transitional region (from the transitional region of regional transmission) to truncated region, can be according to this width with the band width W of boundary belt ₂Set narrowlyer.That is, can be with W ₂Set De Bishi (7) for W ₂Condition narrow.Thereby, have can realize the narrower optical communication system of the optical spectrum that takies, be the speciality of the higher optical communication system of frequency utilization efficient.

Other

In addition, in the above-mentioned explanation separately of the 1st, the 2nd, the 3rd, the 4th execution mode, recorded and narrated the situation that optical transmitter 100 and optical receiver 200 separately exist in different places, in identical optical communication apparatus, realized above-mentioned optical transmitter 100 and the function of optical receiver 200, situation about between these optical communication apparatus, communicating but also can have as other execution mode certainly.And then, in the case, there is use that optical transmitter 100 is carried the execution mode that the so-called transponder (transponder) in identical casing or on the plate constitutes with optical receiver 200 certainly.

According to the respective embodiments described above, can be provided in the light ofdm communication system, can reduce the light ofdm communication system and the optical transceiver of the receiving sensitivity deterioration of the Beat Signal that results between subcarrier.In addition, can use the frequency band of the analog component (driver, D/A change-over circuit, preamplifier, A/D change-over circuit etc.) that in transmitter and receiver, uses to suppress to realize light ofdm communication system and optical transceiver as about 2 times parts of signal band, thereby, can provide than communication system and optical transceiver cheaply in the past.And then, in the respective embodiments described above, owing to use the direct detection receive mode, thus simpler with coherent reception mode structure compared, thereby communication system and optical transceiver cheaply can be provided.

6. structure example

Optical communication system for example is to have optical transmitter and optical receiver, and wherein optical transmitter maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates in symbol time, send with light signal via optical fiber,

Optical receiver carries out opto-electronic conversion to propagate the light signal that comes in this optical fiber, and original numerical data is reproduced in each sub-carrier signal demodulation,

Optical transmitter possesses: send signal processing part, in symbol time numerical data is mapped to mutually orthogonal a plurality of subcarriers and modulate, this sub-carrier signal after the modulation is carried out contrary fast fourier transform (contrary FFT) generate the baseband OFDM signal; With the electric light converter section, this baseband OFDM signal is modulated to laser, generate the light ofdm signal; Alternately send the light ofdm signal of 2 different wavelength according to each symbol time;

Optical receiver has: at least one group of above group that is made of delayed interference portion and balanced type photoelectric conversion part, this delayed interference portion makes the part of the light ofdm signal that receives from above-mentioned optical transmitter via optical fiber postpone symbol time and synthetic with the light ofdm signal, and this balanced type photoelectric conversion part is converted to the signal of telecommunication with light signal; With the received signal handling part, analog digital (A/D) conversion is carried out in the output of above-mentioned photoelectric conversion part, signal after this A/D conversion is carried out fast Fourier transform (FFT) obtain sub-carrier signal,, with data demodulates the data after the demodulation are converted to serial data and reproduce original numerical data according to this sub-carrier signal.

In above-mentioned optical communication system, one of its feature is, the wavelength of the light ofdm signal that above-mentioned optical transmitter will be made of a plurality of subcarriers and carrier wave alternately changes according to each symbol time and sends.

In above-mentioned optical communication system, one of its feature is, the difference of the frequency of the frequency of above-mentioned carrier wave and single subcarrier is at least frequency bandwidth over half of a plurality of subcarrier integral body.

In above-mentioned optical communication system, one of its feature is in above-mentioned received signal handling part, according to each subcarrier that obtains by FFT, to deduct the data of the preceding subcarrier of 1 code element.

In above-mentioned optical communication system, one of its feature is that above-mentioned optical receiver is by constituting with the lower part: filter, and the light of two wavelength of the light ofdm signal that will send here from above-mentioned optical transmitter is respectively to two output port partial waves; The received signal handling part, make the light of two output ports of above-mentioned filter distinguish incidents to two delayed interference portions, the output separately of these two delayed interference portions is converted to the signal of telecommunication respectively with two above-mentioned balanced type photoelectric conversion parts, this signal of telecommunication is carried out analog digital (A/D) conversion respectively, 2 signals after this A/D conversion are alternately selected according to each OFDM symbol time, selected signal is carried out fast Fourier transform (FFT) and obtains sub-carrier signal, according to this sub-carrier signal with data demodulates, data after the demodulation are converted to serial data, reproduce original numerical data.

In above-mentioned optical communication system, one of its feature is, is substantially equal to symbol time the time of delay of above-mentioned delayed interference portion.

Utilizability on the industry

The present invention for example can use in optical communication system.

Description of reference numerals

100: optical transmitter

110,110-1,110-2: send signal processing part

111,223: the parallel conversion of serial (S/P) portion

112: subcarrier-modulated portion

113: contrary fast Fourier transform (FFT) portion

114,226: parallel serial conversion (P/S) portion

115: Cyclic Prefix inserts (CPI) portion

116,116-1: digital-to-analogue conversion (D/A) portion

117-1,117-2:1x2 electric switch

120,120-2: electric light converter section

121,121-1: laser

122,122-1,122-2: light I-Q modulator

123,123-1,123-2,123-3,123-4,126:RF oscillator

124,124-1,124-2: phase shifter

125,125-1,125-2,125-3: adder

127,127-1,127-2,229:2x1 electric switch

The 128:Mach-Zehnder optical modulator

129,130,240,400: filter

200: optical receiver

210,210-2,210-3: balanced type photoelectric conversion part

211-1: photodiode

212-1,212-2,212-3: preamplifier

213: subtracter

220,220-2: received signal handling part

221,221-1,221-2: analog digital conversion (A/D) portion

222,222-1: Cyclic Prefix is removed (CPR) portion

223: the parallel conversion of serial (S/P) portion

224: fast Fourier transform (FFT) portion

225: subcarrier demodulation portion

227,227-1: differential amplifier

228,228-1: delay circuit

230,230-1,230-2: delay interferometer

231,232: optical coupler

233: time of delay portion

300: optical fiber

Claims

1. optical communication system, wherein optical transmitter maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates in symbol time, send with light signal via optical fiber, optical receiver carries out opto-electronic conversion to propagate the light signal that comes in this optical fiber, original numerical data is reproduced in each sub-carrier signal demodulation, it is characterized in that

Above-mentioned optical transmitter possesses:

Send signal processing part, in symbol time, numerical data is mapped to mutually orthogonal a plurality of subcarriers and modulate, generate the baseband OFDM signal by the sub-carrier signal after the modulation; With

The electric light converter section is modulated to laser with this baseband OFDM signal, generates the light ofdm signal;

Alternately send wavelength different light ofdm signal with above-mentioned electric light converter section according to each symbol time by above-mentioned transmission signal processing part;

Above-mentioned optical receiver has:

The group that at least one is made of delayed interference portion and balanced type photoelectric conversion part, this delayed interference portion makes the part of the light ofdm signal that receives from above-mentioned optical transmitter via optical fiber postpone symbol time and synthetic with the light ofdm signal, and the light signal after this balanced type photoelectric conversion part will synthesize is converted to the signal of telecommunication; With

The received signal handling part obtains sub-carrier signal by the output of above-mentioned photoelectric conversion part, with data demodulates, reproduces original numerical data according to this sub-carrier signal.

2. optical communication system as claimed in claim 1 is characterized in that,

The wavelength of the light ofdm signal that above-mentioned optical transmitter will be made of a plurality of subcarriers and carrier wave alternately changes according to each symbol time and sends.

3. optical communication system as claimed in claim 2 is characterized in that,

The difference of the frequency of the frequency of above-mentioned carrier wave and single subcarrier is at least frequency bandwidth over half of a plurality of subcarrier integral body.

4. as each described optical communication system in the claim 1～3, it is characterized in that,

Above-mentioned optical transmitter,

For the 1st carrier wave and the 2nd big carrier wave of frequency ratio the 1st carrier wave,

Generation comprises a plurality of subcarriers and is in the 1st smooth ofdm signal of the 1st carrier wave in the lower sideband ripple of this subcarrier,

Generation comprises a plurality of subcarriers and is in the 2nd smooth ofdm signal of the 2nd carrier wave in the upper side band wave of this subcarrier,

The 1st smooth ofdm signal and the 2nd smooth ofdm signal are alternately sent according to each symbol time.

5. as each described optical communication system in the claim 1～4, it is characterized in that,

In above-mentioned received signal handling part, according to the output of above-mentioned photoelectric conversion part is carried out the conversion of analog digital A/D and will change after signal carry out fast fourier transform and each subcarrier of obtaining, deduct the data of 1 symbol time subcarrier before, obtain the subcarrier of each symbol time.

6. as each described optical communication system in the claim 1～4, it is characterized in that,

Above-mentioned optical receiver also possess with from the light ofdm signal of above-mentioned optical transmitter according to wavelength respectively to the filter of two output port partial waves;

Make light from two output ports of above-mentioned filter to the incident respectively of two above-mentioned delayed interference portions, the output separately of these two above-mentioned delayed interference portions is converted to the signal of telecommunication respectively with two above-mentioned balanced type photoelectric conversion parts;

Above-mentioned received signal handling part is alternately selected according to each symbol time the signal of telecommunication after changing, and obtains sub-carrier signal according to selected signal, reproduces original numerical data.

7. as each described optical communication system in the claim 1～6, it is characterized in that,

Above-mentioned electric light converter section has:

Light source portion is alternately exported the light of 2 wavelength according to each symbol time;

Oscillating portion produces the sine wave signal and the cosine wave signal of two frequencies respectively;

The 1st adder to the real part of baseband OFDM signal, alternately adds the cosine wave signal of two frequencies according to each symbol time;

The 2nd adder to the imaginary part of baseband OFDM signal, alternately adds the sine wave signal of two frequencies according to each symbol time; With

Light I-Q modulator is used from the signal of above-mentioned the 1st adder and the 2nd adder the light from above-mentioned light source portion is modulated, output light ofdm signal.

8. optical communication system as claimed in claim 7 is characterized in that,

The sine wave signal of above-mentioned two frequencies is opposite phases.

9. as each described optical communication system in the claim 1～6, it is characterized in that,

Above-mentioned electric light converter section has:

Oscillating portion produces the cosine wave signal of two different frequencies respectively;

Adder to the real part of baseband OFDM signal, alternately adds the cosine wave signal of two frequencies according to each symbol time;

Light I-Q modulator uses imaginary part from the signal of above-mentioned adder and baseband OFDM signal to modulating and export from the light of above-mentioned light source portion;

Above-mentioned smooth sending part also has a band pass filter that blocks of two carrier waves that the both sides at ofdm signal are occurred.

10. as each described optical communication system in the claim 1～6, it is characterized in that,

Above-mentioned transmission signal processing part has:

Oscillating portion produces sine wave signal and cosine wave signal;

The 1st adder adds cosine wave signal from above-mentioned oscillating portion to the real part of baseband OFDM signal; With

The 2nd adder adds sine wave signal from above-mentioned oscillating portion to the imaginary part of baseband OFDM signal;

Above-mentioned electric light converter section has:

Light source portion is exported the light of 2 wavelength respectively;

The 1st smooth I-Q modulator uses signal from above-mentioned the 1st adder to modulating from the side in the light of above-mentioned light source portion; With

The 2nd smooth I-Q modulator uses signal from above-mentioned the 2nd adder to modulating from the opposing party in the light of above-mentioned light source portion;

In the above-mentioned electric light converter section, alternately import to the above-mentioned the 1st smooth I-Q modulator and the above-mentioned the 2nd smooth I-Q modulator according to each symbol time from the signal of above-mentioned the 1st adder with from the signal of above-mentioned the 2nd adder, above-mentioned electric light converter section closes ripple and output with the output of the above-mentioned the 1st smooth I-Q modulator and the output of the above-mentioned the 2nd smooth I-Q modulator.

11 An optical transmitter; optical communication system is an optical transmitter; in the optical communication system; the optical transmitter within the symbol period of the digital data is mapped to a plurality of orthogonal sub-carriers are modulated; transmitting optical signals via the optical fiber; optical receiver in the optical fiber in the optical signal propagation delay portion and the symbol time, and the optical signal synthesis; the synthesized optical signal after photoelectric conversion; solutions of each sub-carrier signal tune to reproduce the original digital data; wherein

Above-mentioned optical transmitter possesses:

Alternately send the light ofdm signal of 2 different wavelength according to each symbol time by above-mentioned transmission signal processing part and above-mentioned electric light converter section.

12. transponder, it is the transponder in the optical communication system, in this optical communication system, optical transmitter maps to mutually orthogonal a plurality of subcarriers with numerical data and modulates in symbol time, send with light signal via optical fiber, optical receiver carries out opto-electronic conversion to propagate the light signal that comes in this optical fiber, and original numerical data is reproduced in each sub-carrier signal demodulation, it is characterized in that

Above-mentioned transponder possesses above-mentioned optical transmitter and above-mentioned optical receiver;

Above-mentioned optical transmitter possesses:

Alternately send the light ofdm signal of 2 different wavelength according to each symbol time by above-mentioned transmission signal processing part and above-mentioned electric light converter section;

Above-mentioned optical receiver has: